Novel Synthesis Techniques for Preparation of Ultrahigh-Crystalline

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Novel Synthesis Techniques for Preparation of Ultrahigh-Crystalline Vanadyl Pyrophosphate as a Highly Selective Catalyst for n-Butane Oxidation Ali Asghar Rownaghi*,† and Yun Hin Taufiq-Yap‡ Department of Chemical Engineering, Monash UniVersity, Victoria 3800, Australia, and Department of Chemistry, UniVersiti Putra Malaysia, 43400, Selangor, Malaysia

The vanadyl hydrogen phosphate hemihydrate (VOHPO4 · 0.5H2O), with well-defined crystal size, has been successfully synthesized for the first time, using a simple one-step solvothermal process that was free of surfactants and water and had a short reaction time and low temperature. The synthesis was performed via the reaction of V2O5 and H3PO4 with an aliphatic alcohol (1-propanol or 1-butanol) at high temperatures (373, 393, and 423 K) in a high-pressure autoclave. The mixture of reactions directly gave the VOHPO4 · 0.5H2O, which is a valuable commercial catalyst precursor for the selective oxidation of n-butane to maleic anhydride. The catalyst precursors were dried by microwave irradiation. The reaction conditions (by varying the reducing agent and reaction temperature) were used further for optimization of the crystallite size, surface area, morphology, and activity of the nanostructure of vanadium phosphate oxide [(VO)2P2O7] catalyst. This new method significantly reduced the preparation time and lowered the production temperature (50%) of catalyst precursor (VOHPO4 · 0.5H2O), when compared to conventional hydrothermal synthesis methods. The as-prepared (VO)2P2O7 catalyst under various conditions exhibited remarkably different physical and chemical properties, indicating the potential of the suggested method in tuning the crystalline structure and surface area of (VO)2P2O7 to improve its catalytic performance. It was found that the length of the carbon chain in an alcohol and reaction temperature in the solvothermal condition had a great impact on the chemical and physical properties of resulting catalysts. Interestingly, there was no trace of VO(H2PO4)2, which is an impurity noted to be readily formed under solvothermal preparation conditions. The precursors and catalysts were characterized using a combination of powder X-ray diffraction (XRD), Brunauer-Emmett-Teller (BET) surface area measurement, scanning electron microscopy (SEM), and temperature-programmed reduction in hydrogen (H2-TPR). A correlation between the surface area of the catalyst and the activity was observed. Finally, the yield of maleic anhydride was significantly increased from 21% for conventional catalyst to 38% for the new solvothermal catalyst. 1. Introduction Vanadyl pyrophosphate catalyst (VPO) is well-known as a commercial catalyst for the selective oxidation of n-butane to maleic anhydride, and experimental studies have shown that vanadium phosphates are also effective catalysts for propane and pentane partial oxidation.1-4 Most of the attention has focused on the vanadyl hydrogen phosphate hydrate phase (VOHPO4 · 0.5H2O), which is transformed under reaction conditions to give a complex mixture of V4+ and V5+ phases.5 The preferred industrial catalyst is synthesized from VOHPO4 · 0.5H2O to form an active catalyst comprised of (VO)2P2O7 with RII-, γ-, and δ-VOPO4 by in situ activation in n-butane/air.6 Although many preparation methods have been cited, virtually all are based on the reaction between a vanadium compound (typically V2O5), a phosphorus compound (typically H3PO4), and a reducing agent/solvent (typically an alcohol).7 The alcohol is intercalated into the layer structure of the VPO compounds, and the subsequent removal on heat treatment plays a central role in establishing the final surface area of the catalyst. The alcohol can also play a role in establishing the morphology of the vanadyl hydrogen phosphate hydrate, which, because the transformation to the final catalyst is topotactic, controls the morphology of the final catalyst.8 Therefore, the solvent clearly plays a valuable and identifiable function in the preparation of VPO materials. When the alcohol is used as a reducing agent, * To whom correspondence should be addressed. Tel.: +613 9905 3147. Fax: +613 9905 5689. E-mail addresses: ali.rownaghi@ eng.monash.edu.au, [email protected]. † Department of Chemical Engineering, Monash University. ‡ Department of Chemistry, University Putra Malaysia.

it is oxidized to form an aldehyde or ketone.7 Most researchers agree that it is essential that the desired precursor VOHPO4 · 0.5H2O is produced in a form that is as pure as possible. In particular, it is known that the material VO(H2PO4)2 can be deleterious when present as an impurity in the catalyst precursor, because it reduces the surface area of the activated catalyst and, consequently, these catalysts display poorer catalyst performance.8,9 Various synthesis methods have been developed to obtain vanadyl hydrogen phosphate hemihydrate (VOHPO4 · 0.5H2O) with controlled catalytic properties. Among them are four widely used techniques: (i) the VPA method, which was used in the early literature10 with water as the solvent; (ii) the VPO method, which is considered to be the standard preparation method and is used in most academic studies;7,12 (iii) the VPD method, which was first disclosed by Horowitz and co-workers12 and further described by Johnson et al.,7 and has subsequently been investigated in detail;5,13,14 and (iv) the hydrothermal method, by which these catalysts have been synthesized by slow hydrothermal synthesis, requiring the presence of surfactants as the template agent at 423 K for 144 h.15,16 Recently, the solvothermal technique has attracted much interest in the synthesis of novel and essential materials.17,18 However, the literature reveals no studies focused on the preparation of vanadium phosphate catalyst using solvothermal synthesis at lower high temperatures (373, 393, and 423 K). We will show that VOHPO4 · 0.5H2O can be crystallized in alcohols at temperatures lower than that required by hydrothermal conversion. In this paper, we report the successful preparation of crystalline vanadyl hydrogen phosphate hemihydrate (VOHPO4 · 0.5H2O) via this new technique. The direct (one-

10.1021/ie902011a  2010 American Chemical Society Published on Web 01/29/2010

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Table 1. Preparation Condition and Methods of the VPO Catalysts precursor catalyst VPHA1 VPHA2 VPHA3 VPHB1 VPHB2 VPHB3 VPH1

VPOA1 VPOA2 VPOA3 VPOB1 VPOB2 VPOB3 VPO1

VPH2

VPO2

preparation condition V2O5 + o-H3PO4 + 1-propanol + 373 K V2O5 + o-H3PO4 + 1-propanol + 393 K V2O5 + o-H3PO4 + 1-propanol + 423 K V2O5 + o-H3PO4 + 1-butanol + 373 K V2O5 + o-H3PO4 + 1-butanol + 393 K V2O5 + o-H3PO4 + 1-butanol + 423 K VPO method (V2O5 + o-H3PO4 + benzyl alcohol + isobutanol) VPD method (VOPO4 · 2H2O + isobutanol)

precursor heating microwave microwave microwave microwave microwave microwave microwave microwave

step) synthesis is performed in an aliphatic alcohol (such as 1-propanol or 1-butanol) as the solvent and V2O5 and H3PO4 as starting materials without employing any high cost template or surfactant. We have been exploring a controlled solvothermal synthesis of orthorhombic phase VOHPO4 · 0.5H2O via a simple variation of reducing agents. We previously attempted to modify the preparation procedure for VOHPO4 · 0.5H2O synthesis under reflux conditions at ambient pressure in either isobutanol or ethylene glycol and water.19-21 In this study, however, we have developed a preparation method using a high-pressure technique. The vanadium phosphate catalysts were synthesized in an autoclave system under higher reaction temperature and pressure. This synthesis strategy provides some substantial advantages, including the following: (i) product is obtained in excellent yield in a one-pot synthesis, using a self-assembly strategy; (ii) the technique is simple and low cost (free of surfactants and water); (iii) no impurity-phase VO(PO3)2 is produced in the resultant catalyst; (iv) a lower amount of reducing agent is used; (v) a higher active surface area catalyst is produced as compared to conventional methods; (vi) preparation time is reduced by 50%; and (vii) reaction temperature is significantly reduced. In this study, vanadium phosphate catalysts were prepared via three different methods, namely, (i) conventional VPO, (ii) conventional VPD, and (iii) the new solvothermal method synthesis method. The information presented by this work provides a basis for the development of an improved solvothermal method for the synthesis of VPO catalyst. The effects of the carbon number, polarity, and viscosity of the alcohol and the drying of vanadyl hydrogen phosphate hemihydrate by microwave (MW) heating on the physicochemical properties and morphology of the solid solution and catalytic reactivity for n-butane oxidation are discussed. 2. Experimental Section 2.1. Catalyst Preparation. V2O5 and H3PO4 (85%) were purchased from Fluka and Merck suppliers, respectively. All alcohols were purchased from BDH Chemical and were used without any further purification. Preparation conditions under which the samples were synthesized are listed in Table 1. Three different techniques for VOHPO4 · 0.5H2O synthesis under ambient and high-pressure conditions were performed: the VPO method, the VPD method, and the proposed new solvothermal method (called VPS). 2.1.1. The VPO Method. The VPO method is considered to be the standard preparation method and is used in most academic studies. In this method, V2O5 was refluxed with H3PO4 with an alcohol, and a blue precursor was obtained as a precipitate. This precipitate was composed almost exclusively of the hemihydrate VOHPO4 · 0.5H2O.7 A detailed description of precursor production has been reported in previous studies by Rownaghi and Taufiq-Yap22 and by other research teams.23-25 The light blue solid was recovered by filtration and dried for 5

min using a microwave irradiation method (this solid is denoted as VHP1). The heating conditions were a frequency of 2450 MHz and an output power of 300 W. 2.1.2. The VPD Method. Vanadyl phosphate dihydrate (VOPO4 · 2H2O, VPD) was prepared according to the procedure described by Johnson et al.,7 at ambient pressure; this process has subsequently been improved using different reducing agents and promoters.14,19-21 Details regarding the preparation and characterization of VOPO4 · 2H2O can be found in Rownaghi et al.23 and are omitted here for the sake of brevity. The reduction of VOPO4 · 2H2O with alcohols at ambient pressure produced VOHPO4 · 0.5H2O, which is a valuable commercial catalyst precursor for the oxidation of n-butane to maleic anhydride.23 The resulting blue solid (which is denoted as VHP2) was recovered by filtration and then heated for 5 min in a microwave, as mentioned previously. 2.1.3. The Proposed New Solvothermal Method (VPS). In this research, we report the excellent yield in a one-pot synthesis by a self-assembly strategy of crystalline vanadyl hydrogen phosphate hemihydrate (VOHPO4 · 0.5H2O) via this technique. Vanadium(V) pentoxide (V2O5) and ortho-phosphoric acid (oH3PO4) were used as the reactants without any pretreatment, and primary aliphatic alcohols (1-propanol and 1-butanol) were added as the solvent and reducing agent. The autoclave (50mL capacity, Teflon-lined stainless steel) was filled to about two-thirds of the total volume and then sealed. In the next step, the autoclave was heated and maintained at high temperatures (373, 393, and 423 K) for typically 72 h. The system was then allowed to cool to ambient temperature. The resulting precipitate (blue solid) was then recovered by filtration and repeatedly washed with hot distilled water and acetone to remove the residual reactants and byproduct. The resulting hot blue solid was recovered by vacuum filtration, and washed with hot distilled water. The obtained blue solid was then subjected to 5 min of MW heating, as mentioned previously. All precursors synthesized via the three heating methods previously indicated contained VOHPO4 · 0.5H2O, which was identified by powder X-ray diffraction (XRD). The calcination of obtained precursors was conducted in a furnace. The precursors were heated at the rate of 2 °C/min at 733 K for 6 h under a flow of 1.5% n-butane/ air mixture. 2.2. Catalyst Characterization. 2.2.1. X-ray Diffraction (XRD). XRD was performed to determine the bulk crystalline phases of the catalysts using a diffractometer (Shimadzu, Model XRD 6000) employing Cu KR radiation (λ ) 1.54439 Å) to generate diffraction patterns from powder crystalline samples at ambient temperature. The spectra were scanned at a rate of 2.0°/min in the 2θ range of 10°-60°. 2.2.2. BET Surface Area. The total surface area of catalysts was measured by the Brunauer-Emmett-Teller (BET) method using nitrogen adsorption at 77 K. The experiment was performed using a nitrogen adsorption/desorption analyzer (Sorptomatic 1990 series). 2.2.3. Redox Titration. Redox titration was performed using the method of Niwa and Murakami26 to estimate the average oxidation number of vanadium. 2.2.4. Scanning Electron Microscopy (SEM). Surface morphology of the catalysts was observed under scanning electron microscopy (SEM), using a LEO operated at accelerating voltages of 15 kV. The samples were prepared by dispersing the catalyst powder on a metallic sample holder, using doublesided tape to keep them on the holder. The samples were coated with a thin layer of gold using BIO-RAS sputter coater. Micrographs were recorded at various magnifications.

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Figure 1. (a) Powder XRD patterns of vanadyl hydrogen phosphate hemihydrate (VOHPO4 · 0.5H2O, VHP) derived by solvothermal reaction in 1-propanol for 72 h at 373 (VHPA1), 393 (VHPA2), and 423 K (VHPA3), as well as via conventional VPO and VPD methods. ((001) and (130) are the main peaks for VOHPO4 · 0.5H2O.) (b) Powder XRD patterns of vanadyl hydrogen phosphate hemihydrate (VOHPO4 · 0.5H2O, VHP) derived by solvothermal reaction in 1-butanol for 72 h at 373 (VHPB1), 393 (VHPB2), and 423 K (VHPB3), as well as via conventional VPO and VPD methods. ((001) and (130) are the main peaks for VOHPO4 · 0.5H2O.)

Figure 2. (a) Powder XRD patterns of vanadium phosphorus oxid ((VO)2P2O7, VPO) derived by solvothermal reaction in 1-propanol for 72 h at 373 K (VPOA1), 393 K (VPOA2), and 423 K (VPOA3), as well as via conventional VPO (VPO1) and VPD (VPO2) methods. ((020) and (204) are the main peaks for (VO)2P2O7.) (b) Powder XRD patterns of vanadium phosphorus oxide ((VO)2P2O7, VPO) derived by solvothermal reaction in 1-butanol for 72 h at 373 K (VPOB1), 393 K (VPOB2), and 423 K (VPOB3), as well as conventional VPO (VPO1) and VPD (VPO2) methods. ((020) and (204) are the main peaks for (VO)2P2O7.)

2.2.5. Temperature-Programmed Reduction in H2 (H2TPR). Temperature-programmed reduction in H2 (H2-TPR) was performed to observe the reducibility of the VPO catalyst, using an apparatus (ThermoFinnigan, Model TPDRO 1110) utilizing a thermal conductivity detector (TCD). H2-TPR experiments were conducted using a quartz reactor tube (4 mm inner diameter), in which an ∼25-mg sample was mounted on loosely packed quartz wool. Prior to H2-TPR measurement, each catalyst was pretreated in N2 at 473 K (at a heating rate of 10 K min-1 and a hold time of 30 min) and then cooled under helium gas flow. The reduction gas was composed of 5 vol % H2 in argon. The reaction temperature was programmed to increase at a constant rate of 10 K min-1. A thermocouple in contact with the catalyst allowed the temperature to be controlled. The amount of H2 uptake during the reduction was measured by a thermal conductivity detector (TCD). The effluent H2O that formed during H2-TPR was adsorbed by a 5A molecular sieve adsorbent. The error on the peak temperature was determined to be (15 °C. 2.3. Catalytic Test. The oxidation of n-butane to maleic anhydride was performed in a fixed-bed flow microreactor containing a standard mass of catalyst (0.25 g) at 673 K with

gas hourly space velocity (GHSV) of 2400 h-1. Prior to use, the catalysts were pelleted and sieved to produce particles with 250-300 µm in diameter, and n-butane and air were fed to the reactor via calibrated mass flow controllers to give a feedstock composition of 1.7% n-butane in air. The products were injected into an online gas chromatograph for in situ analysis. The reactor is composed of stainless steel tube with the catalyst held in place by plugs of quartz wool. A thermocouple was located in the center of the catalyst bed and temperature difference was typically (1 K. Carbon mass balances of g95% were typically observed. 3. Results and Discussion 3.1. X-ray Diffraction (XRD). The solid solution of VOHPO4 · 0.5H2O was produced isothermally by solvothermal processing at temperatures of 373, 393, and 423 K. Figure 1a shows the XRD patterns of the VOHPO4 · 0.5H2O solid solution prepared via the conventional VPO and VPD methods, and using 1-propanol in the solvothermal method. The diffractions at 2θ ) 15.48°, 19.56°, 24.14°, 27.00°, and 30.34° are identical to

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Table 2. XRD Data of Solvothermal and Conventional Nanostructure VPO Catalysts fwhma (Å)

Table 3. Physical and Chemical Properties of Solvothermal and Conventional Catalysts

crystallite sizeb (nm)

catalyst

020 phase

204 phase

020 phase

204 phase

VPOA1 VPOA2 VPOA3 VPOB1 VPOB2 VPOB3 VPO1 VPO2

0.200 0.308 0.450 0.236 0.231 0.277 0.891 0.574

0.188 0.120 0.310 0.277 0.215 0.267 0.462 0.455

40.1 26.0 17.8 33.9 34.7 28.9 9.0 14.0

43.1 67.5 26.1 29.2 37.7 30.3 17.5 17.8

a

Full width at half-maximum (fwhm) of the 020 or 204 reflection. b Crystallite sizes were calculated accordingly to the Debye-Scherrer equation.30

VOHPO4 · 0.5H2O precursors (JCPDS File Card No. 37-269) and show no traces of the impurity VO(H2PO4)2.27,28 Similar trends were observed for the entire precursor studied, but the method at the evaluated temperatures lead to intensity at the peaks of 2θ ) 15.5° and 30.4° being indexed to the 001 and 130 planes, respectively.27 However, the 001 peak at 2θ ) 15.5° for the solvothermal precursor (VHPA1) was shown to be significantly more intense (4-fold to 5-fold), compared to the same peak of the precursor prepared by the conventional VPO (VHP1) and VPD (VHP2) methods. It is known that the 001 plane of the VOHPO4 · 0.5H2O phase transforms to the topologically similar 020 plane of (VO)2P2O7, which is believed to be responsible for the catalytic activity in n-butane oxidation.29 The XRD patterns of the four catalysts that were prepared by calcination of the precursors at 723 K under the flow of n-butane/air are shown in Figure 2a. As can be seen, the catalyst prepared by the solvothermal method, (VO)2P2O7 (JCPDS File Card No. 34-1381) was the only product formed. The catalyst prepared by the solvothermal method at 373 K gave highly crystalline structure and exposure of the crystallographic phase 020. The main peaks appeared at 2θ ) 22.9°, 28.4°, and 29.38°, which corresponded to the 020, 204, and 221 planes, respectively. Peak broadening in the 020 phase was significantly smaller for the catalyst prepared via the solvothermal method (VPOA1) at 373 K than the catalyst prepared via the conventional VPO (VPO1) and VPD (VPO2) methods (see Figure 2a), because of the faster crystal growth in the solvothermal method at 373 K. The peaks became narrower in the 020 phase, yet the d-spacing (the 2θ position) of each peak was fixed. The average crystallite size of an individual phase can be estimated by applying peak broadening analysis to the corresponding XRD diffraction using the Debye-Scherrer equation.30 Therefore, from the results obtained in this study (shown in Table 2), the average particle size of the VPO catalyst prepared by the solvothermal method (VPOA) and using 1-propanol as a reducing agent was estimated to be ∼40 nm. In view of the well-established role of the 020 plane of the (VO)2P2O7 phase in catalyzing the selective oxidation of butane to maleic anhydride, the synthesis of phases with preferential exposure of this plane would be of great significance in increasing the activity of (VO)2P2O7 catalyst. The XRD patterns for the precursors and catalyst using 1-butanol as a reducing agent and prepared by the solvothermal and conventional VPO and VPD methods are shown in Figures 1b and 2b, respectively. As can be seen from the figures, by using 1-butanol, the same trend as 1-propanol was observed. However, the 001 peak at 2θ ) 15.5° for solvothermal precursor (VHPB2) was shown to be significantly more intense (4-fold

catalyst

surface areaa (m2 g-1)

[V5+] (%)

[V4+] (%)

average oxidation number of vanadium in bulkb

VPOA1 VPOA2 VPOA3 VPOB1 VPOB2 VPOB3 VPO1 VPO2

34 29 22 23 21 7 17 24

17 10 8 10 5 21 27 21

77 90 92 90 95 79 73 79

4.17 4.10 4.08 4.10 4.05 4.21 4.27 4.21

a After pretreatment at 423 K in a vacuum. titration.26

b

Estimated by redox

Figure 3. Relationship between intensity of the 020 plane and catalyst surface area for the VPO catalyst derived by solvothermal reaction for 72 h at 373, 393, and 423 K.

to 5-fold), compared to the same peak of the precursor prepared by the conventional VPO (VHP1) and VPD (VHP2) methods. The catalyst prepared by the solvothermal method at 373 and 393 K gave a highly crystalline structure and exposure of the crystallographic plane 020. The average crystallite size, relative to the corresponding XRD diffraction using the Debye-Scherrer equation30 obtained in this study (Table 2) and the average particle sizes of VPO catalyst prepared by the solvothermal method (VPOB) and using 1-butanol as a reducing agent, was estimated to be ∼30 nm. Figures 1b and 2b show the XRD patterns of precursors and catalyst with 1-butanol as reducing agent. As can be seen in the XRD patterns, the same trend as that observed for 1-propanol was observed. However, the 001 peak at 2θ ) 15.5° for the solvothermal precursor (VHPB2) was shown to be significantly more intense (4-fold to 5-fold), compared to the same peak of the precursor prepared via conventional VPO (VHP1) and VPD (VHP2) methods. The catalyst prepared by the solvothermal method at 373 and 393 K gave a highly crystalline structure and exposure of the crystallographic 020 phase. The average crystallite size obtained in this step by the Debye-Scherrer equation30 is shown in Table 2. The XRD patterns for the results obtained were conducted isothermally at 373, 393, and 423 K; a reaction time of 72 h shows that the chain of alcohol (number of carbons) plays an important role in the phase content and the particle size the orthorhombic structure31 of the VOHPO4 · 0.5H2O phase and the (VO)2P2O7 catalyst. 3.2. BET Surface Area Measurement and Redox Titration. The BET surface areas of the catalysts prepared by the solvothermal method at different isothermal temperatures are shown in Table 3. BET results indicated that the surface area of the catalyst prepared via solvothermal methods is higher than those reported for the VPO catalyst prepared via the hydrothermal method.15 The obtained surface area values were

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Figure 4. Relationship between catalyst surface area and reaction temperature for the VPO catalyst derived by solvothermal reaction for 72 h at 373, 393, and 423 K.

consistent with crystallite size data and SEM morphology. However, the values obtained (depending on the chain of alcohol) were slightly higher than those for the organic and dihydrate methods, respectively.7,12 Increases in the rate crystal growth at any temperature affect the crystallize structure, and

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the XRD peaks become narrower with reduced peak broadening. The relationship between surface area and intensity in the 020 phases (Figure 3) shows the same trend as that observed for the catalyst prepared by the solvothermal method; the intensity of the 020 plane increases as the surface area increases. In Figure 4, the surface area of the catalyst obtained by the solvothermal method is plotted against the reaction temperature. The results show that, with the increase in the reaction temperature, the surface area of the catalyst gradually decreases. This can be attributed to this fact that catalysts synthesized at higher temperatures have bigger size (due to occurring of agglomeration of particles) with more amorphous structure than catalysts obtained at lower temperatures with rosette structure. However, the thermal decomposition of mixtures of V2O5 and H3PO4 in primary alcohols (C3-C4) shows a nanocrystalline VPO catalyst with a catalyst crystallite size of 20-40 nm and large BET surface areas, compared to the catalyst prepared by hydrothermal methods. The VPO catalyst prepared in 1-propanol produces ultrahigh-quality (VO)2P2O7 crystallites and leads to large surface areas and small crystallite sizes. In conclusion, as can be seen in Table 1 and Figure 4, the surface area of the catalyst prepared by the solvothermal method had a linear

Figure 5. Scanning electron microscopy (SEM) micrographs of VPO catalyst derived by solvothermal reaction for 72 h in 1-propanol (VPOA1), 1-butanol (VPOB), and conventional VPO (VPO) and VPD (VPO2) methods.

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relationship with temperature and reaction media: the longer the chain alcohols and the higher the reaction temperature, the smaller the surface area. The average oxidation number of vanadium and percentage of V4+ and V5+ oxidation states are also summarized in Table 3. It is widely accepted that the valence state of vanadium plays an important role in the selective oxidation of n-butane to MA.32 The average oxidation number for vanadium in the microwave catalysts is higher than conventionally made catalysts. The calculated values are presented in Table 3. This difference might influence the catalytic properties of vanadium phosphate catalyst in oxidation reactions and could be attributed to the formation of a V5+ phase (VOPO4) during solvothermal synthesis. Therefore, the polarity and the type of the alcohol used as reducing agent exhibit stronger impact on catalysts properties. 3.3. Scanning Electron Microscopy (SEM). The SEM micrographs of the solvothermal and conventional VPO and VPD catalysts are shown in Figure 5. The crystallites clearly are not single-crystal faces, because the surfaces are marked with many indentations. SEM images reveal a novel morphology of solvothermal-MW-prepared catalysts. Among the characteristic vanadium phosphate rosette-shaped particles, solvothermal catalysts displayed a platelike structure with an average particle size of